Perched atop the sheer coastal cliffs of Ireland's Aran Islands, ridges of giant boulders have puzzled geologists for years. What forces could have torn these rocks from the cliff edges high above sea level and deposited them far inland? While some researchers contend that only a tsunami could push these stones, new research finds that plain old ocean waves, with the help of some strong storms, did the job.

Share This

This is the boulder ridge around the coastline of the Aran Islands. New research finds that storm waves have formed these ridges, despite the contention of some researchers that only a tsunami would have enough power to do this.

Credit: Ronadh Cox

Perched atop the sheer coastal cliffs of Ireland's Aran Islands, ridges of giant boulders have puzzled geologists for years. What forces could have torn these rocks from the cliff edges high above sea level and deposited them far inland?

Related Articles

While some researchers contend that only a tsunami could push these stones, new research in The Journal of Geology finds that plain old ocean waves, with the help of some strong storms, did the job.

And they're still doing it.

The three tiny Aran Islands are just off the western coast of Ireland. The elongated rock ridges form a collar along extended stretches of the islands' Atlantic coasts. The sizes of the boulders in the formations range "from merely impressive to mind-bogglingly stupendous," writes Dr. Rσnadh Cox, who led the research with her Williams College students. One block the team studied weighs an estimated 78 tons, yet was still cut free from its position 36 feet above sea level and shoved further inland.

Armed with equations that model the forces generated by waves, some researchers have concluded that no ordinary ocean waves could muster the force necessary to move the largest of the boulders this high above the ocean surface and so far inland. The math suggests the rocks in the ridges could only have been put there by a tsunami.

The equations tell one story. The islands' residents tell another. According to some locals, enormous rocks have moved in their lifetimes, despite the fact that there hasn't been a tsunami to hit the islands since 1755.

"Unless you have little green men from mars doing this on the quiet, it must be storm waves," Cox said.

While the anecdotes from residents are interesting, Cox and her team went in search of more concrete evidence. The clincher came when the team compared modern high-altitude photos of the coastline to set of meticulous maps surveyed in 1839. The 19th century surveyors, who Cox describes as "possibly the most anal men on the planet," carefully mapped not only the boulder ridges, but all of the criss-crossing stone walls that farmers built between fields. The researchers digitized the maps and overlaid them on the modern images, using the walls to line the two up accurately.

"Not only did they map every wall, they did it right. The maps aren't even off by even a meter."

The overlay of the new photos with the old maps shows definitively that sections of the ridges have moved substantially since 1839 -- nearly 100 years after the most recent tsunami. Some sections moved inland at an average rate of nearly 10 feet per decade. In some places, the ridge had run over and demolished field walls noted on the old maps.

Other lines of evidence corroborate residents' accounts of recent movement. When the boulders were ripped from the bedrock, tiny clams that live in cracks and crevices sometimes came along for the ride. Using radiocarbon dating, Cox and her team found that some of the rocks have been pulled from the coastline within the last 60 years. What's more, the researchers have been photographing sections of the ridge during each field season since 2006, and they've documented movement from year to year.

So what of the equations that point to tsunami as the only possible earth mover?

"We've eliminated tsunami and I think we can rule out little green men," Cox said. "What that says is our equations aren't good enough."

Cox thinks the characteristics of the Aran Island shoreline are throwing off the calculations. The Aran cliffs rise nearly vertically out of the Atlantic, leaving very deep water close to the shore. As waves slam into the sheer cliff, that water is abruptly deflected back out toward the oncoming waves. This backflow may amplify subsequent waves. The result is an occasional storm wave that is much larger than one would expect.

"In this kind of environment these would be less rare," Cox said. "You only need a couple of them to move these rocks around. The radiocarbon data show that not only are some boulders moving in recent years, but also that some of them have been in the ridges for hundreds and even a couple of thousand years. Accumulated activity of rare large-wave events over that time could certainly build these structures"

Cox plans to add a physicist to her research team in the near future to try to shed some light on the wave dynamics on the islands, but it's clear from the evidence the team has already gathered that storm waves can do more than some researchers thought.

Following the devastating Indonesian tsunami in 2004, there has been renewed interest in learning about how a tsunami can change the landscape. Cox's findings have important implications for that research.

"There's a tendency to attribute the movement of large objects to tsunami," she said. "We're saying hold the phone. Big boulders are getting moved by storm waves."

More From ScienceDaily

More Earth & Climate News

Featured Research

Mar. 31, 2015  Soil organic matter, long thought to be a semi-permanent storehouse for ancient carbon, may be much more vulnerable to climate change than previously thought. Scientists have found that the common ... full story

Mar. 31, 2015  The ocean is a large reservoir of dissolved organic molecules, and many of these molecules are stable against microbial utilization for hundreds to thousands of years. They contain a similar amount ... full story

Mar. 31, 2015  Using the assessment tool ForWarn, US Forest Service researchers can monitor the growth and development of vegetation that signals winter's end and the awakening of a new growing season. Now these ... full story

Mar. 31, 2015  Geoscientists have revealed information about how continents were generated on Earth more than 2.5 billion years ago -- and how those processes have continued within the last 70 million years to ... full story

Mar. 31, 2015  Until now electric fences and trenches have proved to be the most effective way of protecting farms and villages from night time raids by hungry elephants. But researchers think they may have come up ... full story

Mar. 31, 2015  The volcanologist Stephen Self, an expert on super-eruptions, was the first modern-day scientist to visit Tambora in Indonesia, the site of the largest volcanic eruption in 1,000 years. On the 200th ... full story

Mar. 31, 2015  Researchers have detected a human fingerprint deep in the Borneo rainforest in Southeast Asia. Cold winds blowing from the north carry industrial pollutants from East Asia to the equator, with ... full story

Mar. 31, 2015  Landfills can make a profit from all their rotting waste and a new patent explains exactly how to make the most out of the stinky garbage sites. Decomposing trash produces methane, a landfill gas ... full story

Mar. 31, 2015  As the five-year anniversary of the explosion of the Deepwater Horizon oil rig approaches, a new report looks at how twenty species of wildlife are faring in the aftermath of the ... full story

Mar. 31, 2015  Scientists have discovered why the first buds of spring come increasingly earlier as the climate changes. As the climate changes the sweet spot for seeds comes earlier in the year, so first flowers ... full story

Nov. 20, 2012  The traditional crofting way of life is under threat in Scotland’s Western Isles because of a fundamental misunderstanding of how Atlantic wave action affects their coastlines, a academic has ... full story

Dec. 5, 2011  Researchers discovered that the destructive tsunami generated by the March 2011 Tohoku-Oki earthquake was a long-hypothesized "merging tsunami" that doubled in intensity over rugged ocean ... full story

June 15, 2011  A new survey of barrier islands offers the most thorough assessment to date of the thousands of small islands that hug the coasts of the world's landmasses. The study offers new insight into how ... full story

Mar. 11, 2011  Geologists in the UK have recorded the impact of today's major earthquake, off the coast of Japan, using sophisticated equipment. The magnitude 8.9 quake east of Honshu on March 11, 2011 was ... full story

ScienceDaily features breaking news and videos about the latest discoveries in health, technology, the environment, and more -- from major news services and leading universities, scientific journals, and research organizations.